CA2687161C - Dual polarization planar emitting element and network antenna comprising such emitting element - Google Patents

Abstract

The dual polarization planar emitting element includes an external metal grill, at least one metal patch concentric to the external metal grill and a cavity separating the metal grill and the metal patch. The grill and the patch have a polygon shape delimited by at least four sides, facing two by two. It comprises two orthogonal polarisation directions associated to two electrical orthogonal fields. At least one of the polarisation directions is parallel to two sides of the polygon and each side of the metal patch parallel to one polarisation direction is electrically linked to a zone of the external grill where one of the electrical fields is minimal. The invention presents the advantage of reducing the phenomenon of electrostatic discharges into the planar emitting elements without significant modification of the response of the emitting element subjected to an orthogonal polarised wave. This applies to radiating networks and to network antennae.

Description

Planar radiating element with dual polarization and network antenna having such a radiating element The present invention relates to a planar radiating element dual polarization in which the phenomenon of electrostatic discharges is minimized and to a network antenna comprising such a radiating element.
The invention applies to any type of antenna comprising at least one element planar radiating beam with dual polarization, with radiating networks equipping some antennas and network antennas embedded on a spacecraft, for example on a satellite, such as reflector array antennas or phased array antennas.
A network antenna, such as for example a network antenna reflector (in English: reflectarray antenna) or a network antenna phase control (in English: phased array antenna), has a set of elementary radiating elements assembled into a network radiating one or two dimensions to increase the directivity and the gain of the antenna. In the reflector network antennas, the elements elementary radiators of the network are often made up of a arrangement of patches and slots whose dimensions vary. The form radiating elements, for example square, circular, hexagonal, is usually fixed and unique for the network. The dimensions of the elements radiators are adjusted to obtain a radiation pattern chosen when illuminated by a primary source. In the antennas phased array, the distribution of the signal to the elements radiating network is done using a training dispatcher from beam.
Elementary radiating elements may be constituted by a cavity structure and radiating slots mounted on a metal plane or by a planar structure comprising a metallic radiating patch printed on the surface of a dielectric substrate mounted on a plane metal, the metal patch may include one or more slots as shown for example in Figure 1. Radiant slits

2 can be made of a dielectric material or a material composite such as the superposition of a substrate honeycomb printed thin dielectrics used as the skin of the composite material.
However, for the antenna to be able to support an environment space, we must ensure that the phenomena of electrostatic discharges between the radiating elements are minimized.
It is known to minimize electrostatic discharges on a machine space by connecting all the electrically conductive outer surfaces and all the internal metallic elements of the spacecraft to the structure main metal of the machine. For polarizing radiating elements linear, the earthing can be carried out without any particular problem in connecting the radiating elements to an external metal grid by a wire metal along an axis of symmetry perpendicular to the direction of polarization.
However, for a radiant network consisting of elements radiating elements of planar structure with dual polarization, it is necessary to take into account the polarization of the different elements Radiant. Indeed, a direct connection of the radiating elements between them, for example through a wire, would affect the polarization and the operation of these elements and could destroy the resonances and provoke the excitement of other higher modes. In addition, in the case of a network antenna, the adaptation of the radiating elements could be destroyed.
The present invention aims to remedy this problem by proposing a dual polarization planar radiating element in which the Electrostatic discharge phenomenon is minimized without disturbing the response of the radiating element subjected to a polarized wave orthogonally.

3 One aspect of the invention relates to a planar radiating element dual polarization which has an external metal gate, at least one concentric metal patch to the outer metal grid and a cavity separating the outer metal grid and the metal patch, the grid metallic external part and the metal patch having a polygonal shape delimited by least four opposite sides two by two, in which it comprises two orthogonal polarization directions associated with two electric fields orthogonal, at least one of the directions of polarization being parallel to two sides of the polygon and in which each side of the metal patch parallel to a polarization direction is electrically connected to an area external metal grid where one of the electric fields is minimal.
Advantageously, the polygonal shape of the metal patch is chosen from a form of square, rectangle, cross, hexagon Advantageously, the planar radiating element comprises four orthogonal sides two by two and each side of the parallel metal patch to a polarization direction is respectively connected to one side of the wire rack external perpendicular to said polarization direction.
Preferably, each side of the metal patch parallel to a polarization direction has a center connected to a center on one side of the outer gate perpendicular to said polarization direction.
According to a particular embodiment, the metal patch can have several orthogonal slots forming a cross.
According to another embodiment, the metal patch comprises a external annular patch, at least one internal patch concentric to the patch outer annulus and at least one annular gap separating the patches internal and external, the internal and external patches having the same form polygonal, each side of the internal patch parallel to a direction of polarization being connected to one side of the perpendicular external annular patch at said polarization direction.
Optionally, the internal patch may have a plurality of slots orthogonal forming a central cross.
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4 Preferably, each side of the internal patch parallel to a polarization direction has a center connected to a center on one side of the external annular patch perpendicular to said polarization direction.
According to a particular embodiment, the polygonal shape of the Metallic patches are a cross and the outer grid has a square shape.
According to another particular embodiment, the metal patch has an external annular patch, at least one internal patch concentric to the outer annular patch and at least one annular slot separating the internal and external patches, the internal and external patches having a hexagon shape with two sides parallel to a direction of polarization and four obliquely inclined sides with respect to said direction of polarization and connected two by two by a vertex, each side of the patch external metal parallel to said polarization direction being connected electrically to a top of the inner patch and each side of the patch internal parallel to said polarization direction being connected electrically to a top of the outer metal patch.
The invention also relates to a network antenna comprising at least minus a planar radiating element with dual polarization, the metal grid external of each radiating element being connected to a ground plane metallic network.
Other features and advantages of the invention will appear clearly in the following description given by way of example purely illustrative and not limiting, with reference to the attached schematic drawings who represent:
FIG. 1: a diagram of an example of a network antenna;
figure 2: a diagram of a first element example dual polarization elemental radiator made in planar technology;
FIGS. 3a and 3b: two diagrams, seen from above, of a second and third example elementary radiating element to dual polarization realized in planar technology;

FIGS. 4, 5a, 5b: three schematic views from above of three examples of radiating element, according to the invention;
FIG. 6: a schematic view from above of a fourth example of radiating element, according to the invention;

Figures 7 and 8:
two schematic top views of one of a fifth and sixth example of radiating element, according to the invention;
FIGS. 9a, 9b, 9c: three schematic views from above of three examples of radiating network, according to the invention.
FIG. 1 shows an example of a network antenna 10 comprising a reflector array 11 forming a reflective surface 14 and a source primary 13 to illuminate the reflector array 11 with an incident wave.
The reflector array has a plurality of radiating elements elementary elements arranged in a two-dimensional surface.
In Figure 2 is shown a first example of element elemental radiating element 12 with dual polarization comprising a patch metal printed on an upper face of a substrate 16 provided with a metal mass plane 17 on its underside, the substrate being a dielectric material or a composite material made of a material spacer, for example honeycomb, and fine dielectric materials. The metal patch 15 has two cross-shaped slots 18 made in the center. The shape of the elementary radiating elements 12 can be for example square, rectangular, hexagonal, circular, cross-shaped or any other geometric form. The slots can also be made in a different number of two and their arrangement can be different from a cross. In Figure 2 the slots have the same dimensions but they could be of different dimensions.
In Figure 3a is shown a second example of element Planar radiating light with dual polarization. The radiating element has a shape polygonal, for example square and includes a first metal patch 30, a second external annular metal patch forming a metal ring 31, and an annular slot 32 separating the ring outer metal 31 and the inner metal patch 30. The inner patch, the crown and slot are concentric. When the radiating element is

6 polarized orthogonally by two excitatory waves, the two fields Ev electric and Eh corresponding to the two directions of polarization are orthogonal to each other. The field Ev is parallel to a first side 33 of the radiating element and the Eh field is parallel to a second side 34 of the radiating element, the first and second sides 33, 34 being orthogonal between them. The annular slot 32 is resonant when its circumference is equal to the period of the polarization mode that is established. So, as the shows Figure 3a, the electric field Ev is maximal in some 35 regions of the slot where the electric field Eh is minimal and disappears in other regions 36 where the electric field Eh is maximum. The regions where one of the fields Ev, respectively Eh, disappears gradually are regions where the outer ring is parallel to the direction of polarization corresponding. In places where the electric field Ev, respectively Eh, disappears, it is possible to place a short circuit between the internal patch and the external crown because it will have no effect on the response of the element radiating wave subjected to a polarized wave in this mode. Indeed, as shown in FIG. 3b, for each polarization, the annular slot 32 is equivalent to two half-slits in the form of two half-rings complementarily arranged symmetrically with respect to the mediator of the side parallel to the corresponding polarization. So, for polarization Ev, the annular slot 32 is equivalent to two half-slots 1, 2 disposed symmetrically with respect to the mediator 5 on the side 33. Similarly for the Eh polarization, the annular slot 32 is equivalent to the two half-slots 3, 4 arranged symmetrically with respect to the mediator 6 on the 34 side.
four half-slits consisting of four interlaced half-rings represented in FIG. 3b therefore have for each polarization Ev, Eh, a behavior equivalent to an annular slot as depicted on the Figure 3a.
The radiating elements shown in FIGS. 3a and 3b have also the same behavior as a radiating element that involves short circuits between the inner patch and the outer ring at the locations where the electric field Ev, respectively Eh, disappears, as shown in FIG. 4. In this example, according to the invention, each side of the patch internal metal 30 is electrically connected, for example by means of a wire metal 37, at one side of the outer ring 31 which is orthogonal thereto.

7 Preferably, the wire 37 connects the middle of the patch side internal metal 30 in the middle of the side of the outer ring 31 which is orthogonal. Outside the resonance, short the slots of any which way does not significantly modify the properties of the element beaming. When the slots are close to resonance, this connection electrical power has little effect on the response of the radiating element when is excited by an orthogonally polarized wave such that each direction of polarization is parallel to one of the sides of the patch and the crown external. Indeed, the electric field corresponding to each direction of polarization is maximal in the regions of the slots perpendicular to said polarization direction and is very low, or even zero in the regions slots parallel to said polarization direction.
When each side of the inner patch is connected to the outer ring as described above, the parasitic electrostatic charges that appear on the inner patch are drained to the outer crown. he then just connect the outer ring of the radiating element to ground the antenna or radiating network on which it is mounted for evacuate the electrostatic charges.
As shown in FIG. 5a, during the integration of the element radiating in a radiating network, an external metal grid can be added to drain electrostatic charges to a ground plane metallic network as the plane of mass 17 radiating elements.
The radiating element shown in FIG. 5a comprises a patch metal 15, for example in the form of a square, in which are practiced two orthogonal slots 18, 20 forming a cross. The cross is usually positioned at the center of the metal patch and is such that each slot is parallel to two opposite sides of the square. Alternatively, the cross can have additional orthogonal slots 21, 22, 23, 24 as example a cross, called Jerusalem Cross, shown in Figure 5b which has four additional slots respectively placed orthogonally at both ends of each central slot. The element radiator 39 further comprises an outer metal annular grid 38 delimiting a cavity 41 between the grid and the metal patch. Grid outer annulus and metal patch are concentric and likewise geometric shape. The cavity 41 behaves like a radiant slit and participates in global radiation. The geometric shape of the patch

8 shown in Figures 5a and 5b is a square but the invention is not limited to this type of form. In particular, the invention also applies to patches of rectangular shape or of polygonal shape delimited by minus four opposite sides two by two, such as a hexagon, or shaped cross. According to the invention, each side 42, 43, 44, 45 of the metal patch internal is electrically connected, for example by means of a wire 46, to one side 47, 48, 49, 50 of the external grid 38 which is orthogonal to it.
Preferably, the wire connects the middle of the patch side metallic internal in the middle of the side of the external grid which is orthogonal to it. The same reasoning that applied with the example of Figure 4 remains valid replacing the metal ring 31 by the metal grid 38.
When each side of the internal patch is connected to the external grid as described above, the parasitic electrostatic charges that appear on the patch are drained to the external grid. It is enough so that connect the external grid of the radiating element to the metallic mass of the antenna or the radiating network on which it is mounted to evacuate electrostatic charges.
FIG. 6 represents a third example of a radiating element according to the invention. In this example, the geometric shape of the element radiating is hexagonal and has 6 opposite sides two by two. This radiating element comprises two annular metal patches 61, 62 concentric spaced apart by an annular slot 63. When this element radiating is excited by an orthogonally polarized wave such as one Eh polarization directions is parallel to two opposite sides 64, 65 of the hex, the Ev field is minimal in the regions of the external patch perpendicular to the Ev field, that is the regions of the vertices of the hexagon where the sides 66, 67, 68, 69 which are not parallel to any direction of polarization meet. So each side 72, 73 of the patch internal 62 parallel to one of the directions of polarization Eh is connected electrically at a vertex 70, 71 of the outer patch 61 where the sides 66, 67 and 68, 69 which are not parallel to any direction of polarization together. Similarly, a top 74, 75 of the internal patch 62 where the sides 56, 57, 58, 59 which are not parallel to any direction of polarization join is electrically connected to a side 65, 64 of the external patch 61 parallel to a direction of polarization Eh. As in the examples precedents, when integrating the radiating element into a network

9 radiating, an external metal grid, not shown, is added to drain the electrostatic charges to a metal ground plane of the network such as the ground plane 17 of the radiating elements.
The same principle also applies to radiating elements having a plurality of annular slots 76, 77 and a plurality of metal patches 78, 79, 80, concentric, each annular gap separating two patches as shown in FIGS. 7 and 8. In this case, each side of a first internal metal patch 80 parallel to a direction of polarization is electrically connected to an orthogonal side of a second annular metal patch 79 that surrounds it, and each side of the second annular metal patch 79 parallel to a direction of polarization is electrically connected to an orthogonal side of a third metal patch 78 which surrounds it. And so on for each of the metal patches so that all the internal metal patches to an annular metal patch that surround it have each of their sides parallel to a direction of polarization connected to an orthogonal side of the annular metal patch which surrounds. In addition, the radiating element may comprise a metal grid external annular ring 94 separated from the outer annular patch 78 by a cavity 98. In this case, as described above with reference to FIG.
each side of the third external metal patch 78 is connected electrically to one side of the outer gate 94 which is orthogonal to it.
In FIG. 8, the radiating element comprises an external grid 82 in square shape and a central cross, spaced from the outer grid by a cavity 88. The central cross comprises two annular metal patches 83, 84 cross-shaped separated by an annular slot 85 in the shape of a cross, and two orthogonal slots 86, 87 forming a cross, positioned centrally of the radiating element. The different crosses are such that each slot 85, 86, 87 has regions parallel to a first direction of Ev polarization and parallel regions to a second direction of Eh polarization. Similarly, each annular metal patch 83, 84 and the gate 82 has parallel sides and orthogonal sides to the first polarization direction Ev as well as parallel sides and orthogonal sides at the second direction of polarization Eh. As for the example shown in FIG. 7, each side of a first patch internal metal 84 parallel to a polarization direction is connected electrically to an orthogonal side of a second metal patch annular 83, or the outer metal grid 82 surrounding it. This guy planar radiating element in the form of a cross has the advantage of lead to smaller dimensions than annular slit patterns in elements of square or circular type, since the electric path 5 is lying down. They can therefore be inserted in more mesh networks small, which is favorable for bandwidth performance, and this which improves the response of the network to high-impact waves Figures 9a, 9b, 9c show three examples of network radiating, according to the invention. The network of Figure 9a has two

10 planar radiating elements with dual polarization, each element 39, 40 having a metal patch 15, 19 and an external grid = spaced from the patch by a cavity. The two radiating elements are adjacent and the two outer grids 50, 51 have a side 49 common. Each side of the metal patch is electrically connected to one side orthogonal of the external grid.
The networks of Figures 9b and 9c have four elements planar radiators with dual polarization. In Figure 9b, each element 90, 91, 92, 93 has an internal metal patch 80, a first annular metal patch 79 spaced from the internal patch by a first annular slot 77, a second annular metal patch 78 spaced from the first annular patch 79 by a second annular slot 76, an annular metal grid 94, 95, 96, 97 spaced from the second patch annular metal 78 by a cavity 98. The four radiating elements are adjacent to each other and the four grids have common sides 99, 101, 102, 103 two by two.
In FIG. 9c, each radiating element 104, 105, 106, 107 has two central slots 86, 87 in the form of a cross, a first patch inner annulus 84 surrounding the central cross, a second annular patch 83 external to the first annular patch 84 and spaced from it by a slot annular 85 and an outer annular metal grid 82 of square shape and spaced from the second annular metal patch 83 by a cavity 88, as in Figure 8. The four radiating elements are adjacent between they and the four grids have sides common in pairs.
Each metal patch has sides parallel to a polarization direction connected to an orthogonal side of a metal patch who surrounds it or for the second annular patch, at an orthogonal side of the

11 external metal grille. All electrostatic charges are thus drained to the outer metal grid without disturbing the response of radiating elements subjected to an orthogonally polarized wave. The electrostatic charges are then discharged to a ground plane metallic network by connecting the outer gate to this ground plane metallic.
A radiant network of different sizes and different characteristics can thus be achieved by combining a plurality of elements radiating to form a radiant surface of desired size at a or two dimensions. Elements can all be the same or can be of different structures depending on the type of antenna desired. The network = can then be implanted in a chosen network antenna such as by example that shown in Figure 1 or any other type of antenna network.
Although the invention has been described in relation to modes of particular realization, it is obvious that it is not at all limited and that it includes all the technical equivalents of the means described as well that their combinations if they fall within the scope of the invention. In particular, all combinations of full or annular patches and cross-shaped orthogonal central slots can be made, the cross may have a number of orthogonal slots greater than or equal to for two, such as the simple cross or the Jerusalem cross. Of same, a planar radiating element having a geometric shape hexagonal or cross-shaped can have an external grid shape different, for example of square shape. In addition, radiating elements hexagonal shape may have an internal patch having slots orthogonal centers forming a simple cross or a Jerusalem cross.

Claims (11)

The embodiments of the invention in respect of which an exclusive right of property or privilege is claimed are defined as follows: 1. Dual polarization planar radiating element having a grid external metal, at least one metal patch concentric to the grid external metal and a cavity separating the metal grid and the patch the grid and the patch having a polygonal shape delimited by least four opposite sides two by two, in which it comprises two orthogonal polarization directions associated with two electric fields orthogonal signals Ev and Eh, at least one of the polarization directions being parallel to both sides of the polygon and in which each side of the patch metallic parallel to a polarization direction is electrically connected to one zone of the external grid where one of the electric fields Ev or Eh is minimal. Planar radiating element according to claim 1, wherein the form polygonal metal patch is selected from a square shape, from rectangle, cross or hexagon. Planar radiating element according to claim 2, wherein has four orthogonal sides two by two and that each side of the metal patch parallel to a polarization direction is connected respectively at one side of the outer gate perpendicular to said direction of polarization. Planar radiating element according to claim 3, wherein each side of the metal patch parallel to a polarization direction has a center connected to a center on one side of the external grid perpendicular to said direction of polarization. Planar radiating element according to one of claims 1 to 4, in which wherein the metal patch further comprises at least two orthogonal slots forming a central cross. Planar radiating element according to one of claims 1 to 5, in which wherein the metal patch has an outer annular patch, at least one concentric inner patch with external annular patch and at least one slit annular separating the internal and external patches, the internal and external having the same polygonal shape and in which each side of the internal patch parallel to a polarization direction is connected to one side of the patch annular external perpendicular to said polarization direction. Planar radiating element according to claim 6, wherein each side of the internal patch parallel to a polarization direction has a center connected to a center on one side of the outer annular patch perpendicular to said direction of polarization. Planar radiating element according to one of claims 6 or 7, in which which the internal patch has at least two orthogonal slots forming a central cross. 9. planar radiating element according to one of claims 6 to 8, in which the polygonal shape of the metal patches is a cross and in that the outer grid has a square shape. The planar radiating element according to claim 2, wherein the patch metal has an external annular patch, at least one internal patch concentric to the outer annular patch and at least one annular slot separating the internal and external patches, the internal and external patches having a hexagon shape having two sides parallel to a direction of polarization and four obliquely inclined sides with respect to said direction of polarization and connected two by two by a vertex, in which each side of the external metal patch parallel to said polarization direction is joined electrically to a top of the internal patch and in that each side of the patch internal parallel to said polarization direction is electrically connected has a top of the outer metal patch. 11. Antenna network that includes at least one planar radiating element to dual polarization according to any of claims 1 to 10 in which the external metal grid of each radiating element is connected to a plane of metallic mass of the network.